Production of eukaryotic proteins and nucleic acid molecules in C. elegans

ABSTRACT

Plasmid vectors for expression in  Caenorhabditis elegans  harbouring a heat inducible promoter nucleotide sequence, a synthetic intron nucleotide sequence optionally containing a Shine-Dalgarno sequence for efficient shuttling between  C. elegans  and  E. coli , optionally a nucleotide sequence coding for a nuclear localisation signal or secretion signal, a nucleotide sequence coding for a recognizable tag, optionally a nucleotide sequence coding for a fluorescent protein, a nucleotide sequence coding for a protease cleavage site, a multiple cloning site containing a nucleotide sequence coding for an eukaryotic, such as human, protein or a nucleic acid molecule and a nucleotide sequence coding for termination of translation, are described. Methods of particularly large scale production of eukaryotic, such as human, proteins and nucleic acid molecules in nematodes are also described.

The present invention relates to the production of post-translationally modified eukaryotic proteins in general and human proteins in particular, in the nematode Caenorhabditis elegans. It also includes the production of post-translationally modified nucleic acid molecules, such as tRNA. It further includes the co-translational labeling of the expressed proteins with identifiable labels such as ²H, ¹³C, ¹⁵N, Se-methionine, Se-cystein or non-natural amino acids. Similarly the labeling of nucleic acid molecules with ²H, ¹³C and ¹⁵N.

BACKGROUND

There are several alternatives for the production of eukaryotic proteins in different expression systems. The following expression systems are currently in use.

Bacteria

Many E. coli expression systems are commercially available. Some examples are pET (Promega), pQE (Qiagen), pGEX (Amersham Pharmacia), ptrcHIS (Invitrogen), pDUAL (Stratagene). The advantage of E. coli systems are that they are cheap and very easy to use. The main disadvantage is that many eukaryotic proteins do not fold properly when expressed in E. coli and form insoluble aggregates. Codon usage is very different from that in higher eukaryotes. Often eukaryotic proteins must be modified following translation in order to be able to fold into the proper structure and/or to become activated. E. coli is not able to carry out complex post translational modifications such as acetylation, N- and O-linked glycosylation and, acylation and phosphorylation which are exclusively performed by eukaryotic cells.

The levels of expression vary enormously from protein to protein. The yield of recombinant protein from 1 liter of E. coli culture amounts typically to about 10 mg. In rare cases amounts of hundreds of milligrams of recombinant protein per liter E. coli culture can be obtained.

Yeast

The yeast Pichia pastoris is a well established system for expressing recombinant proteins. Several companies sell the relevant plasmid vectors. Invitrogen Corp. for example sells the pPIC set of plasmids. The advantages of Pichia is that being a eukaryote, the post-translational modifications are more similar to those that occur in humans or higher eukaryotes. Pichia is easy and fast to transform. It is also easy to grow on a large scale. Expression levels vary considerably. Levels as high as 12 grams/liter have been reported.

Insect Cells

Insect cells can also be used to express recombinant proteins. Several companies sell the relevant plasmid vectors and cell lines. Invitrogen's systems are DES, InsectSelect and MaxBac. The advantages of insect cells are that, being multicellular eukayotes, insects are much more like humans than yeast are. The disadvantages are (i) insect cells are much more difficult to grow and maintain than bacterial or yeast cells (ii) they are more expensive to cultivate (iii) they require sterile incubators (iv) the expression levels are much lower than those seen with the yeast or bacterial systems.

Human Cell Lines

Human cell lines can also be used, but they require growth factors in order to keep them alive. Today, human growth factors are very expensive, and this makes human cell lines bad candidates for e.g. growth factor production.

Nematodes

Nematodes, small roundworms, are one branch of eukaryotic organisms that have so far not been exploited for large-scale protein or nucleic acid production. Nematodes are very simple animals and have served as a developmental model system ever since 1949 (Dougherty E C and Nigon V., J. Parasitol. (1949) 35, 11; Brenner S in a letter to Max Perutz, 5 Jun. 1963). Especially the development of each of the 959 cells in the nematode C. elegans is well characterized and its entire genome was recently sequenced and is now publicly available (“The C. elegans Sequencing Consortium” Genome Sequence of the nematode C. elegans: A platform for investigating biology. Science (1998) 282, 2012-2018). Nematodes are eukaryotic organisms that are genetically much more closely related to humans than bacteria, about 60% of their proteins are homologous to human proteins.

What makes nematodes interesting as a protein expression system for production of eukaryotic and in particular human proteins is the fact that they are equipped with the necessary machinery to perform post-translational modifications on proteins. Hence, proteins (peptide drugs) produced in nematodes are virtually identical to the natural human proteins and as a result may have fewer undesirable side effects and a higher specific activity requiring lower dosages. Other advantages of the nematode expression system include high yields of expressed protein, its low maintenance costs, its ease of use and that one can easily scale up the production.

Expression of human beta-amyloid peptide in transgenic C. elegans to produce muscle-specific deposits immunoreactive with anti-beta-amyloid polyclonal and monoclonal antibodies has been described by C. D. Link (Link C. D., Expression of human beta-amyloid peptide in transgenic Caenorhabditis elegans, Proc. Natl. Acad. Sci. (1 995) 92,9368-9372), and he suggests that his invertebrate model may be useful for in vivo investigation of factors that modulate amyloid formation.

The international patent application WO 00/54815 discloses expression of DNA or proteins in C. elegans by using an expression vector comprising a promoter that directs the gene expression to the excretory cell of C. elegans. The reason for the protein expression is not production and isolation of a protein but for discovery of novel molecules, i.e. drugs, involved in the cell motility, cell shape and cell outgrowth process, and to establish their function.

DESCRIPTION OF THE INVENTION

The present invention provides an in vivo expression system for production of eukaryotic, such as human, proteins and nucleic acid molecules that is easy to handle, inexpensive, genetically stable and easy to scale up. The nematode expression system of the invention is suitable for the large-scale production of ultra pure recombinant human proteins. Proteins and nucleic acid molecules produced will contain all the modifications that are typical for higher organisms (eukaryotes), such as acetylation, N- and O-linked glycosylation and, acylation, phosphorylation and cleavage of signal sequences etc. These modifications are crucial for the specificity of a medically interesting protein in signaling pathways.

The novel nematode protein expression system combines the advantages of eukaryotic cells such as post-translational modifications with the simplicity of handling known from E. coli fermentation.

The expression system comprises the nematode Caenorhabditis elegans. Since the number of different plasmids that can be simultaneously injected into C. elegans is in excess of twenty, this enables the simultaneous expression of multiple plasmids harboring e.g. different subunits of large complexes containing proteins and/or nucleic acids.

Examples of eukaryotic proteins that may be produced on an industrial scale with the present invention include: human growth factors, growth factor receptors (membrane bound or soluble part) for basic research on stem cells and for medical applications such as stem cell based treatment of heart disease, diabetes, cancer, and diseases of the nervous system, including Parkinson's and Alzheimer's disease. In addition monoclonal antibodies, G-proteins, G-protein coupled receptors, and large, multi-subunit protein-RNA complexes such as polymerases, telomerase and splicing factor complexes. Beside potential medical applications, the produced proteins and nucleic acids can be used for structure characterization by X-ray crystallography, electron crystallography or NMR where one studies post-translational modified proteins and nucleic acids. The C. elegans expression system can also be used for labeling of eukaryotic proteins with ²H, ¹³C, ¹⁵N, Se-Met, Se-Cys or non-natural amino acids for crystallographic applications or with ²H, ¹³C, or ¹⁵N, for NMR experiments.

One aspect of the present invention is directed to a plasmid vector for expression in Caenorhabditis elegans comprising in the 5′ to 3′ direction of transcription operably linked to each other a heat shock promoter nucleotide sequence, a synthetic intron nucleotide sequence optionally containing a Shine-Dalgamo sequence for efficient shuttling between C. elegans and E. coli, optionally a nucleotide sequence coding for a nuclear localisation signal or a secretion signal, e.g selected from naturally occurring signal sequences, such as from C. elegans or the signal sequence of the protein or nucleic acid molecule that is to be expressed, a nucleotide sequence coding for a recognisable tag, optionally a nucleotide sequence coding for a fluorescent protein, a nucleotide sequence coding for a protease cleavage site, a multiple cloning site containing a nucleotide sequence coding for an eukaryotic, such as human, protein or a nucleic acid molecule, and a nucleotide sequence coding for termination of translation.

The nucleotide sequence order in the plasmid may be modified so that the multiple cloning site is followed by the nucleotide sequence coding for a protease cleavage site, the optional nucleotide sequence coding for a fluorescent protein, optionally the nucleotide sequence coding for a nuclear localization signal or a secretion signal and the nucleotide sequence coding for a recognizable tag.

Examples of the nucleotide sequence coding for a protease cleavage site include cleavage sites for the proteases TEV, Thrombin and Factor Xa.

In an embodiment of the plasmid vector, the synthetic intron nucleotide sequence contains the Shine-Dalgamo sequence AGGAG, the nucleotide sequence coding for a nuclear localization signal is SEQ ID NO: 3, the sequence coding for a recognizable tag is a sequence coding for a 6-His tag, a 10His tag or a 12-His tag, i.e. 6, 10 or 12 histidine residues that enable easy purification on Ni chelating columns, the nucleotide sequence coding for a fluorescent protein is a nucleotide sequence coding for the green fluorescent protein with the sequence SEQ ID NO: 8, the nucleotide sequence coding for a protease cleavage site is a sequence coding for a protease cleavage site, that enables later cleaving off of the 6, 10 or 12 histidine residues.

In a preferred embodiment the plasmid, lacking a nucleotide sequence coding for an eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO: 1. The plasmide has no nucleotide sequence coding for a nuclear localization signal. The artificial intron starts at 480 and ends at 521, (gtatgtttcga atgatactaa cataacatag aacattttca g), then follows the 6-His-tag sequence, 547 to 564, (cat cac cat cac cat cac), and a linker sequence, 565 to 594, connects the His-tag to the sequence coding for the TEV protease recognition site: 595 to 618. Then comes the multiple cloning site (MCS)(start at 619).

In another preferred embodiment the plasmid, lacking a nucleotide sequence coding for an eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO: 2. The artificial intron starts at 480 and ends at 521 (gtatgtttcga atgatactaa cataacatag aacattttca g), then follows the nucleotide sequence coding for a nuclear localisation signal(NLS): start at pos 533, end at 580 (ctagtgctca gaaaaaatga ctgctccaaa aagaagcgt aaggtgcc). After the NLS comes the 6-His-tag sequence 588 to 605 (catcaccatc ccatcac). A linker sequence (606 to 635) connects it to the sequence coding for the TEV protease recognition site: 636 to 656, which is followed by the multiple cloning site (start at 658).

For cloning purposes, the NLS used in the plasmids is a bit longer than the essential NLS DNA sequence. (The NLS was cloned into the plasmid pre-cut with the restriction enzymes Nhel and Ncol). The essential NLS sequence (558 to 568: ccaaagaagaagcgtaaggtgcc c, [the last c comes from the Ncol cut vector]) translates into the protein sequence PKKKRKV, that is recognized by the nuclear import machinery.

The nuclear localization signal, NLS, is useful for the following reason. When the nematodes are heat shocked and in such a way forced to over-produce the desired human proteins, it may be safer to direct the produced protein into the cell nucleus. This is exactly what the NLS does. The advantage of transporting proteins into the nucleus is that there are no proteases present. These proteases can be present in the cytoplasm and proteases are especially concentrated in organelles called lysosomes. By using a NLS to send the expressed proteins into the nucleus, they are transported in one piece away from potentially dangerous proteases.

The DNA sequence of the green fluorescent protein, GFP, contains additionally three introns in the version in SEQ ID NO: 8. It is primarily used as a luminescent marker to “visualize” that C. elegans expresses the desired protein(s). In the plasmids where it is present, it follows the 6His-tag: e.g. 6His-GFP-TEV-MCS when incorporated into plasmid SEQ ID NO: 1, or NLS-6His-GFP-TEV-MCS when incorporated into plasmid SEQ ID NO: 2.

In yet another preferred embodiment the plasmid, lacking a nucleotide sequence coding for an eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO: 9. The order of the sequences in the plasmid is modified in relation to the sequences in the plasmid SEQ ID NO:1 and the green fluorescent protein with the sequence SEQ ID NO: 8 is included. The sequences come in the order MCS-TEV-GFP-6His.

In still another preferred embodiment the plasmid, lacking a nucleotide sequence coding for an eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO:10. The order of the sequences in the plasmid is modified in relation to the sequences in the plasmid SEQ ID NO: 2 and the green fluorescent protein with the sequence SEQ ID NO: 8 is included. The sequences come in the order MCS-TEV-GFP-NLS-6His.

Inserting the green fluorescent protein (GFP) after the multiple cloning site (MCS) makes it possible to have a fast check for proper protein folding. If the expressed protein of interest, such as a human growth factor, does not fold properly, it will not allow the green fluorescent protein that follows after to fold properly either and as a consequence one does not see green fluorescence. This is a fast test for protein folding. In addition, GFP can be used as a purification tag, either by using ion exchange chromatography following established GFP protocols, or as an affinity tag using immobilized anti-GFP anti-bodies.

The preferred plasmids of the invention are intend to be used in E. coli as well. Therefore they are designed as “shuttle vectors”. The only modification to the above disclosed plasmid sequences is that a so-called “Shine-Dalgarno” sequence is centered about 10 nucleotides before the start codon of transcription, ATG. The Shine-Dalgarno sequence, AGGAG, is a translational initiation signal for E. coli and does not affect C. elegans.

Thus, in plasmid SEQ. ID NO: 1 the Shine-Dalgamo sequence is centered 10 nucleotides before the ATG-6His; in plasmid SEQ ID NO: 2 the Shine-Dalgamo sequence is centered 10 nucleotides before the ATG-NLS; and in plasmids SEQ ID NO: 9 and 10 the Shine-Dalgamo sequence is centered 10 nucleotides before the MCS (the MCS contains an ATG).

The plasmids SEQ ID NO: 1, 2, 9 and 10 contain a protein that makes E. coli bacteria resistant to antibiotica, e.g. ampicillin or carbicillin or to kanamycin. However, these proteins have no effect on C. elegans (e.g. they do not provide any antibiotica resistance to C. elegans).

In a most preferred embodiment of the invention the nucleotide sequence coding for a human protein is a sequence coding for a human growth factor protein. Specific examples of some human growth factor proteins are:

-   SEQ ID NO: 4, the sequence of a growth factor called Wnt2b (Homo     sapiens wingless-type MMTV integration site family, member 2B), -   SEQ ID NO: 5, the sequence of a growth factor called FGF10 (Homo     sapiens keratinocyte growth factor 2 (FGF10)), -   SEQ ID NO: 6, the sequence of a growth factor called KLS (Homo     sapiens KIT ligand soluble fraction), and -   SEQ ID NO: 7, the sequence of a growth factor called BMP10 (Homo     sapiens bone morphogenetic protein 10).

Another aspect of the invention is directed to a method of producing eukaryotic such as human, proteins or nucleic acid molecules in nematodes comprising the steps of injecting one or several plasmid vectors, preferably simultaneously, according to the invention into the gonad of C. elegans hemaphrodites, cultivating the nematodes in a growth medium at a temperature of below 25° C., followed by shifting the growth temperature to values between 30 and 33° C. for induction of protein or nucleic acid molecule expression in several hundred somatic cells, with highest expression levels in neuronal and epidermal cells, and isolating the eukaryotic proteins or nucleic acid molecules from said cells.

In an embodiment of the method of the invention the growth medium comprises bacteria, such as E. coli, as feed for the nematodes. Since C. elegans can feed exclusively on bacteria dispersed in minimal media, this fact can be exploited to label proteins produced in C. elegans. By feeding the worms bacteria that were previously labeled (e.g. with ²H, ¹³C, ¹⁵N, Se-Met, Se-Cys or certain non-natural amino acids for expression of proteins and ²H, ¹³C and ¹⁵N for expression of nucleic acid molecules) according to existing protocols, the respective label will be incorporated into newly produced proteins and nucleotides.

In a preferred embodiment the isolation is performed, in case the plasmid includes a nucleotide sequence coding for a nuclear localization signal, by carefully opening the cells of the nematodes, e.g. by using a “bead beater” (=a blender filled with small zirconium beads)—thereby leaving the cell nuclei intact which contain the expressed proteins or nucleic acid molecules. This is followed by separating the cell nuclei and by dissolving the nuclear membrane to release the expressed proteins and subjecting the mixture to chromatographic purification. For proteins this includes a stationary phase specifically binding to the recognizable tag, e.g. 10His-tagged protein to Ni-chelating beads packed into a purification column, followed by washing off unspecifically bound proteins, and elution under conditions releasing the eukaryotic, such as human, protein-from the column e.g. an imidazole gradient that releases the 10-His-tagged protein. The recognizable tag is then cleaved off by supplying the specific protease corresponding to the protease cleavage site encoded by the plasmid used and having an uncleavable recognizable tag, such as a 6-His-tag, and at the same time performing dialysis against a low concentration of the agent that releases the tag from the stationary phase, (suitably about 10-50 mM if the elution was done with 400-700 mM imidazole), transferring the cut mixture containing the eukaryotic protein with the cut off tag and the protease that itself has an uncleavable recognizable tag, e.g. 6-His-tag, onto a fresh tag specific column, eluting the column to obtain an eluate containing the eukaryotic protein leaving the cut off recognizable tag, e.g. 10-His tag, and recognizably tagged, e.g. 6-His-tagged protease bound to the stationary phase.

In another preferred embodiment the isolation is performed, in case the plasmid lacks a nucleotide sequence coding for a nuclear localisation signal, by mashing the nematodes, to release the expressed eukaryotic proteins and subjecting the mixture to chromatographic purification with a stationary phase specifically binding to the recognizable tag, followed by washing and elution under conditions releasing the eukaryotic protein from the stationary phase, as exemplified in the preceding paragraph.

In case the plasmid used lacks a nuclear localization signal, or an extra precaution to prevent the eukaryotic protein from being attacked by unspecific proteases that can be present in the cell is desired, e.g. for cases where the proteins are degradation sensitive, an alternative or complementary way of protecting the expressed proteins against protease degradation is to inject a separate plasmid, e.g. SEQ ID NO:1 or 2 lacking the nucleotide sequence coding for a protease cleavage site, and containing a nucleotide sequence coding for a general protease inhibitor, such as alpha2-Macroglobulin (α2-M), SEQ ID NO: 11.

Thus, in an additionally preferred embodiment of the method of the invention, the method comprises additionally injecting a plasmid vector comprising operably linked to each other a heat shock promoter nucleotide sequence, a synthetic intron nucleotide sequence optionally containing a Shine-Dalgamo sequence, optionally a nucleotide sequence coding for a nuclear localisation signal, a nucleotide sequence coding for a recognisable tag, optionally a nucleotide sequence coding for a fluorescent protein, a nucleotide sequence coding for a general protease inhibitor, such as the general protease inhibitor SEQ ID NO:11 coding for α2-Macroglobulin, and a nucleotide sequence coding for termination of translation, for co-expression of the general protease inhibitor. In this case, the recognisable tag remains on the expressed general protease inhibitor and it will be bound to the tag specific column (together with the (e.g. 6-His-) tagged protease and the cleaved off (e.g. 10-His-) tag from the eukaryotic protein in the second and last specific column step).

The C. elegans expression system, including the plasmids and the method of producing eukaryotic, such as human, proteins or nucleic acid molecules in nematodes of the invention, is particularly suitable for large scale production of ultra-pure recombinant eukaryotic proteins, in particular human growth factors. Proteins produced will contain the modifications that are typical for higher organisms (eukaryotes), such as acetylation, N- and O-linked glycosylation and, acylation, phosphorylation and cleavage of signal sequences etc. These modifications are crucial for the specificity of a medically interesting protein in signalling pathways. Examples of human (eukaryotic) proteins that may be produced on an industrial scale with the present invention include: human growth factors, growth factor receptors (membrane bound or soluble part) for basic research on stem cells and for medical applications. In addition monoclonal antibodies, G-proteins, G-protein coupled receptors. In particular, the system is designed to allow for shuttling between C. elegans and E. coli in order to study the effects of post-translational modifications. It also allows the labelling of C. elegans produced proteins and nucleic acid molecules with identifiable markers (e.g. ²H, ¹³C, ¹⁵N, Se-Met, Se-Cys, etc.) for NMR and X-ray crystallographic studies, by feeding the nematodes with pre-labelled bacteria. Further, the expression of eukaryotic proteins, such as human, proteins or nucleic acid molecules in C. elegans can be directed to the protective protease reduced environment of the cell nucleus or to certain compartments of the cell, depending on the chosen signal peptide. The system also allows simultaneous expression of proteins from more than 20 plasmids if the reconstruction of large, multi-subunit protein-RNA complexes such as polymerases, telomerase and splicing factor complexes is required.

The invention will now be further illustrated by description of experiments, and it should be understood that the scope of the claims is not restricted to any specifically mentioned details.

Experiments

All manipulations of C. elegans worms were performed using techniques described in Methods in Cell Biology, vol 84; Caenorhabditis elegans: modern biological analysis of an organism, ed. Epstein and Shakes, Academic Press, 1995, or using minor modifications of the methods described therein.

Transgenic C. elegans strains were constructed by injection of plasmid DNA into worms of the genotype unc-36(e251); hmp-1-(zu278)/daf-11(m8ts)sma-1(e30) together with plasmids encoding unc-36(+) and hmp-1(+) (Costa et al., Journal of Cell Biology 141: 297-308 1998). hmp-1(zu278) causes an embryonic lethal phenotype (Costa et al. 1998). Lines were established of the genotypes unc-36(e251); hmp-1(zu278); svEx[unc-36(+) hmp-1(+) hs-gen-1(+)] where ‘gen-1’ denotes the gene encoding the human growth factor.

Worms were heat shocked at 33° C. for two hours by using established procedures. (Stringham E G and Candido, E P M Environmental Toxicology and Chemistry 13: 1211-1220 1994).

Expression Vector Construct

In order to express proteins in C. elegans we have built four plasmid vectors based on the plasmide pPD49,78-umu, SEQ ID NO: 1,2,9 and 10, that allows the heat inducible expression of genes in many different cells. The vector contains a C. elegans heat shock promoter for the ectopic expression of foreign proteins. The promoter is inactive below 25° C. However, shifting the growth temperature to values between 30 and 33° C. results in induction of protein expression at high level in several hundred somatic cells with highest expression levels in neuronal and epidermal cells.

The vectors are designed to make translational fusions. Downstream of the ATG is a sequence encoding a 6-His-tag followed by a TEV protease cleavage site and a multiple cloning site in plasmids SEQ ID NO: 1 and 2.

Micro-injection and Selection

In order to determine the expression level of single protein, we generated several plasmids each containing a different test gene together with appropriate genetic selection markers on separate plasmids.

We injected plasmids into hermaphrodites of the genotype unc-36(e251); hmp-1 (zu278)/daf-11 (m8ts)sma-1(e30) together with plasmids encoding unc-36(+) and hmp-1(+). hmp-1(zu278) causes an embryonic lethal phenotype (Costa et al. 1998). Lines were established of the genotypes unc-36(e251); hmp-1(zu278); svEx[unc-36(+) hmp-1(+) hs-gen-1(+)] where ‘gen-1’ denotes the gene to be tested.

Recombination between different plasmids of more then 600 bp occurs in vivo and transformed first generation F1 progeny are obtained in which the different injected plasmids together form an episome (referred to as an extrachromosomal array). Approximately 1 in 10 F1 transformants give rise to stable lines in which the extrachromosomal array is transmitted from generation to generation without change. Extrachromosomal arrays are relatively stable mitotically so that in any one transformed animal most cells contain the array. By using appropriate co-injection markers encoding essential genes it is possible to obtain strains in which all adult and larval worms in the population contain the array.

Protein Expression

C. elegans is grown from liquid medium in Erlenmeyer flasks on a temperature controlled shaker at 20° C. The liquid growth medium contains the slow growing E. coli strain OP50 on which the nematodes feed. The worms are grown during 7 days after which shifting the growth temperature from 20° C. to 33° C. induces protein production under the control of a heat shock promoter.

The yield of wet worms grown from one liter of initial culture is about 10 g. The green fluorescence protein (GFP) is expressed in about 25% of the cells and leads to a visible florescence signal that is seen under the fluorescence light microscope.

The yield of pure protein from a starting material of 10 to 20 g cultured and induced worms is roughly 0.2 to 1.0 mg.

The human growth factor called Wnt2b (Homo sapiens wingless-type MMTV integration site family, member 2B), was successfully expressed in the worms from the plasmide SEQ ID NO: 1 comprising in the multiple cloning site the nucleotide sequence SEQ ID NO: 4.

In short, the nematodes are grown from simple liquid medium. They grow in 25 fermenters or in Erlenmeyer flasks. The worms have a generation time of about 2-3 days and adult worms grow to about 1 mm in length. Each hermaphrodite produces about 300-500 eggs per generation. They can be repeatedly stored for long periods of time at −80° C. Stable lines can be selected after injection of up to twenty different plasmids into the gonad of hemaphrodites. 

1. Plasmid vector for expression in Caenorhabditis elegans and in Escherichia coli comprising in the 5′ to 3′ direction of transcription operably linked to each other a heat shock promoter nucleotide sequence, a synthetic intron nucleotide sequence containing a Shine-Dalgarno sequence, optionally a nucleotide sequence coding for a nuclear localization signal or a secretion signal, a nucleotide sequence coding for a recognizable tag, optionally a nucleotide sequence coding for a fluorescent protein, a nucleotide sequence coding for a protease cleavage site, a multiple cloning site containing a nucleic acid molecule or a nucleotide sequence coding for a eukaryotic protein, and a nucleotide sequence coding for termination of translation so as to express a eukaryotic protein or nucleic acid molecule in Caenorhabditis elegans and in Escherichia coli wherein the synthetic intron nucleotide sequence contains the Shine-Dalgarno sequence AGGAG, the nucleotide sequence coding for a nuclear localization signal is SEQ ID NO: 3, the sequence coding for a recognizable tag is a sequence coding for a 6-Histidine (His), 10-His or 12-His tag, the nucleotide sequence coding for a fluorescent protein is a nucleotide sequence coding for the green fluorescent protein with the sequence SEQ ID NO: 8, the nucleotide sequence coding for a protease cleavage site is a sequence coding for a Tobacco Etch Virus (TEV) protease cleavage site.
 2. Plasmid vector according to claim 1, wherein the nucleotide sequence order is modified so that the multiple cloning site is followed by the nucleotide sequence coding for a protease cleavage site, the optional nucleotide sequence coding for a fluorescent protein, optionally the nucleotide sequence coding for a nuclear localization signal or a secretion signal and the nucleotide sequence coding for a recognizable tag.
 3. Plasmid vector for expression in Caenorhabditis elegans and in Escherichia coli comprising in the 5′ to 3′ direction of transcription operably linked to each other a heat shock promoter nucleotide sequence, a synthetic intron nucleotide sequence containing a Shine-Dalgarno sequence, optionally a nucleotide sequence coding for a nuclear localization signal or a secretion signal, a nucleotide sequence coding for a recognizable tag, optionally a nucleotide sequence coding for a fluorescent protein, a nucleotide sequence coding for a protease cleavage site, a multiple cloning site containing a nucleic acid molecule or a nucleotide sequence coding for a eukaryotic protein, and a nucleotide sequence coding for termination of translation so as to express a eukaryotic protein or nucleic acid molecule in Caenorhabditis elegans and in Escherichia coli wherein the plasmid, lacking a nucleotide sequence coding for a eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO: 1 or SEQ ID NO:2.
 4. Plasmid vector for expression in Caenorhabditis elegans and in Escherichia coli comprising in the 5′ to 3′ direction of transcription operably linked to each other a heat shock promoter nucleotide sequence, a synthetic intron nucleotide sequence containing a Shine-Dalgamo sequence, a multiple cloning site containing a nucleic acid molecule or a nucleotide sequence coding for a eukaryotic protein, a nucleotide sequence coding for a protease cleavage site, optionally a nucleotide sequence coding for a fluorescent protein, optionally a nucleotide sequence coding for a nuclear localization signal or a secretion signal, a nucleotide sequence coding for a recognizable tag and a nucleotide sequence coding for termination of translation so as to express a eukarvotic protein or nucleic acid molecule in Caenorhabditis elegans and in Escherichia coli wherein the plasmid, lacking a nucleotide sequence coding for a eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO:9 or SEQ ID NO:10.
 5. Plasmid vector according to claim 1, wherein the plasmid, lacking a nucleotide sequence coding for a eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO:
 1. 6. Plasmid vector according to claim 1, wherein the plasmid, lacking a nucleotide sequence coding for a eukaryotic protein or a nucleic acid molecule, has the nucleotide sequence SEQ ID NO:
 2. 